Scribe line channels are formed between semiconductor dies that are formed on a gallium nitride (GaN) layer using an aluminum nitride-based (AlN-based) core substrate. The scribe line channels are formed to expose a release layer under the GaN layer, which enables the release layer to be etched through the scribe line channels to remove the semiconductor dies from the AlN-based core substrate with minimal to no damage to the AlN-based core substrate. In this way, the scribe line channels enable the AlN-based core substrate to be reused for subsequent GaN layer growth, and increase the number of times that the AlN-based core substrate can be reused to form GaN-based semiconductor devices. This reduces the cost and complexity of manufacturing GaN-based semiconductor devices.

A method for producing a semiconductor power device, includes forming a gate trench from a surface of a semiconductor layer toward an inside thereof. A first insulation film is formed on an inner surface of the gate trench. The method also includes removing a part on a bottom surface of the gate trench in the first insulation film. A second insulation film having a dielectric constant higher than SiO.sub.2 is formed in such a way as to cover the bottom surface of the gate trench exposed by removing the first insulation film.

A process for producing semiconductor structures comprising one of more layers of Group III/IV Compounds deposited onto a template using PVD sputtering the resulting semiconductor structures is provided according to the invention. The Group III or Group IV material may be gallium, hafnium, indium, aluminum, silicon, germanium, magnesium and/or zirconium. The anion provided by a reactive gas may be nitride, oxide, arsenide, or phosphide. The flow of the reactive gas to the vacuum chamber used to react with the sputtered Group III or Group IV target material for produce the Group III/IV Compound layer onto the template is modulated during a duty cycle during the PVD sputtering process between a target-rich condition and a reactive gas-rich condition to enhance the efficiency of the PVD sputtering process and improve the crystallinity of the Group III/IV Compound layer within the resulting semiconductor structure.

A semiconductor structure and method for manufacturing thereof are provided. The semiconductor structure includes a silicon substrate having a first surface, a III-V layer on the first surface of the silicon substrate and over a first active region, and an isolation region in a portion of the III-V layer extended beyond the first active region. The first active region is in proximal to the first surface. The method includes the following operations. A silicon substrate having a first device region and a second device region is provided, a first active region is defined in the first device region, a III-V layer is formed on the silicon substrate, an isolation region is defined across a material interface in the III-V layer by an implantation operation, and an interconnect penetrating through the isolation region is formed.

Methods for depositing a boron nitride film on a substrate are disclosed. More particularly, the disclosure relates to methods that can be used for depositing a boron nitride film by a PECVD process. The method comprises providing a substrate into a reaction chamber, and executing a cyclical deposition process comprising a plurality of deposition cycles, ones from the plurality of deposition cycles including providing a boron precursor into the reaction chamber and providing a deposition plasma gas into the reaction chamber.

A monolithic component includes a field-effect power transistor and at least one first Schottky diode inside and on top of a gallium nitride substrate.

A semiconductor device includes a first III-V nitride-based layer, a second III-V nitride-based layer, a nitride-based transition layer, and a nitride-based transistor. The first III-V nitride-based layer is disposed over a substrate by applying a first V/III ratio in a first range. The second III-V nitride-based layer is disposed over the first III-V nitride-based layer by applying a second V/III ratio in a second range, in which the first range and the second range are mutually exclusive. The nitride-based transition layer is disposed between the first III-V nitride-based layer and the second III-V nitride-based layer to connect the first III-V nitride-based layer with the second III-V nitride-based layer, in which the nitride-based transition layer is formed by applying a third V/III ratio in a third range between the first range and second range. The nitride-based transistor is disposed over the second III-V nitride-based layer.

Utility of an ECR plasma technique is enhanced. A film forming apparatus 1 deposits, on a surface of a substrate SUB, first target particles emitted by bombardment of ions (ions making ECR plasma) with a cylindrical target TA mounted on a cylindrical-target mounting section 27 and second target particles emitted by bombardment of ions (ions making plasma which is different in density from the ECR plasma) with a disk target TA2 mounted on a disk-target mounting section 31.

A semiconductor device according to some embodiments includes: a transfer substrate, a semiconductor layer, and an adhesive layer between the transfer substrate and the semiconductor layer. The adhesive layer includes a lower portion and first and second protrusions, and the semiconductor layer comprises an upper portion and first and second protrusions. The first and second protrusions of the adhesive layer are in contact with the upper portion of the semiconductor layer, the first and second protrusions of the semiconductor layer are in contact with the lower portion of the adhesive layer, the first protrusion of the adhesive layer is disposed between the first and second protrusions of the semiconductor layer, and the second protrusion of the semiconductor layer is disposed between the first and second protrusions of the semiconductor layer.

Provided are a crack-free laminated film and a structure including this laminated film. This laminated film includes: a buffer layer; and at least one layer of gallium nitride base film disposed on the buffer layer. Moreover, the compression stress of the entire laminated film is 2.0 to 5.0 GPa.